In this paper we will show an alternative way to avoid possible difficulties that may arise from a singular submatrix B.ĪB - Any first-order optical system (or ABCD-system) can be associated with a linear canonical integral transformation, described by Collins integral as long as the submatrix B is non-singular. To avoid the singular case, Moshinsky and Quesne have shown a decomposition of a symplectic ABCD-matrix with a singular B, as a cascade of two matrices that do not have such a singularity the way to find these matrices, however, is not easy. N2 - Any first-order optical system (or ABCD-system) can be associated with a linear canonical integral transformation, described by Collins integral as long as the submatrix B is non-singular. T1 - ABCD-systems with singular sub-matrix B In particular, we will be able to present the linear canonical integral transformation (whether or not with a singular submatrix B) in the basic form of a separable fractional Fourier transformation this Fourier transformer then acts on rotated input coordinates, and is followed by a further rotation of the output coordinates, by a magnifier, and by a multiplication with a quadratic phase function (a lens).", The resulting decomposition of the entire first-order optical system then shows a physically attractive way to overcome the singular case in the Collins integral. We propose a decomposition of the ortho-symplectic system in the form of a separable fractional Fourier transformer embedded in between two rotators. Starting with the Iwasawa decomposition of a first-order optical system as a cascade of an ortho-symplectic system (a system that is both symplectic and orthogonal), a magnifier, and a lens, a further decomposition of the ortho-symplectic system is considered for the practically important case that the submatrices A, B, C, and D have dimensions 2 x 2. ![]() ![]() In this paper we will show an alternative way to avoid possible difficulties that may arise from a singular submatrix B. In particular, we will be able to present the linear canonical integral transformation (whether or not with a singular submatrix B) in the basic form of a separable fractional Fourier transformation this Fourier transformer then acts on rotated input coordinates, and is followed by a further rotation of the output coordinates, by a magnifier, and by a multiplication with a quadratic phase function (a lens).Ībstract = "Any first-order optical system (or ABCD-system) can be associated with a linear canonical integral transformation, described by Collins integral as long as the submatrix B is non-singular. ![]() ![]() Any first-order optical system (or ABCD-system) can be associated with a linear canonical integral transformation, described by Collins integral as long as the submatrix B is non-singular.
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